Stay wet or else: three ways in which plants can adjust hydraulically to their environment

The literature on whole-plant acclimation to drought is reviewed and it is proposed that leaf-level homeostasis in water status is attained during ontogeny largely thanks to whole-plant changes in physical resistance to liquid water flow caused by morphological and anatomical adjustments. It is show...

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Bibliographic Details
Published in:Journal of experimental botany 2006, Vol.57 (15), p.3963-3977
Main Authors: Maseda, Pablo H, Fernández, Roberto J
Format: Article
Language:English
Subjects:
Acclimatization
Allometry
Biological and medical sciences
Biological Transport
Cell biochemistry
Cell physiology
Drought
Environment
Fundamental and applied biological sciences. Psychology
hydraulic architecture
hydraulic resistance
Hydraulics
Leaf area
Models, Biological
Ontogeny
Pine trees
Plant cells
Plant Development
Plant Leaves - anatomy & histology
Plant Leaves - growth & development
Plant Leaves - metabolism
Plant physiology and development
Plant roots
Plant Transpiration
Plants
Plants - anatomy & histology
Plants - metabolism
Review Article
Soil water
Water - metabolism
Xylem
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Summary:The literature on whole-plant acclimation to drought is reviewed and it is proposed that leaf-level homeostasis in water status is attained during ontogeny largely thanks to whole-plant changes in physical resistance to liquid water flow caused by morphological and anatomical adjustments. It is shown that, in response to water deficits, plant resistance changes at different levels (tissue, organ, individual), levels that are correlated with the time scale of the response. It was found that such adjustments apparently tend to increase resistance to flow in the short term and to reduce it in the long term. A critical view of those findings is provided based on the principle that drought-induced changes cannot be analysed separately from the allometric changes that take place through ontogeny, as for example proposed by the widely cited hydraulic limitation hypothesis. A graphic synthetic model is presented according to which developmental responses to water deficits operate largely through reductions in whole-plant water transport capacity, combined with more or less strong reductions in leaf area (different 'hydraulic allometries'), depending on the intrinsic tolerance of leaf tissues to partial desiccation. The model is used to show that, as the result of such adjustments, the water transport capacity per unit leaf area can decrease, remain constant, or increase, and it is argued that the expected leaf-level response would be different in each case, respectively involving a decreased, constant, or increased potential for transpiration. The article ends with a plea to collect the evidence needed to evaluate the occurrence of these three different response types across taxa and their association with different environments, including the reanalysis of existing data.
ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/erl127